Ferrofluids (FFs) or magnetic nanofluids are incredible smart materials consisting of ultrafine magnetic nanoparticles suspended in a liquid carrier medium, which exhibit both fluidity and magnetic controllability. Studies involving the dynamics and physicochemical properties of these magnetic nanofluids are an interdisciplinary area of research attracting researchers from different fields of science and technology. Herein, a comprehensive Review on the different aspects of FF research is presented. First, the synthesis and stabilization of various types of FFs are discussed followed by their physicochemical features such as polydispersity, magnetic behavior, dipolar interactions, formation of chainlike aggregates, and long‐range ordering. The Review also details the rheological and thermal properties, dynamic instabilities, phase behavior, and particle assemblies in FFs to form complex multipolar geometries, photonic nanostructures, labyrinth structures, thin films, and droplets. Many important characterization techniques for probing FF properties are also briefly discussed, and the numerous innovative applications and future prospects of FFs are outlined.
Shape-memory polymer
composite (SMPC) blends with thermo-responsive
shape memorizing capability have received increasing interest and
have been a grooming research area due to their various potential
applications. In this work, we report three thermo-responsive SMPCs
derived from poly(ε-caprolactone) (PCL) and the polystyrene-block-polybutadiene-block-polystyrene-tri-block copolymer (SBS) encapsulated with CuO, Fe2O3, and CuFe2O4, namely, SMPC–CuO, SMPC–Fe
2
O
3
, and SMPC–CuFe
2
O
4
, respectively.
We have also synthesized the neat shape-memory polymer matrix SMP in the context of the effect of the metal oxide encapsulates
on the shape-memory property. Neat SBS rubber and PCL are used as
the polymer-elastomer blend matrix to form SMP. The objective
of this study is to understand the effect of these three metal oxide
nanofillers encapsulated within the SMP matrix and their
thermal, mechanical, and shape-memory properties. Morphological, thermal,
mechanical, and shape-memory properties of the prepared SMPCs are
completely characterized. It is revealed that the addition of nano-metallic-oxide
fillers into the polymeric matrix significantly improved the overall
properties of SMPCs. The tensile test confirmed that SMPC–CuFe
2
O
4
possesses
a high tensile modulus and is found to be very rigid when compared
to other SMPCs. The shape fixing property is found in the increasing
order as follows: SMPC–CuO > SMPC–Fe
2
O
3
> SMP > SMPC–CuFe
2
O
4
. The better thermal, mechanical,
and shape-memory performances were shown by the SMPC–Fe
2
O
3
composite,
and thus, it can be considered as the better shape-memory polymer
nanocomposite among all others. An optimum storage modulus was attained
by SMPC–Fe
2
O
3
among the SMPCs. More interestingly, we
have developed a microvalve actuator system using SMPC–Fe
2
O
3
,
which could be useful for promising microsystem applications.
Metal-organic frameworks built from [Fe 3 (μ 3-O)(COO) 6 ] clusters and fumaric acid ligand, the so-called MIL-88 A(Fe) is a wellknown environment-friendly promising material for many applications. In this paper, three different morphologies of MIL-88 A(Fe) such as rod, diamond and spindle have been synthesized separately by reacting FeCl 3 * 6H 2 O and fumaric acid in 1 : 1 metal-ligand stoichiometric ratio using two different solvents such as water and DMF via hydrothermal method. The morphology of the products and their particle sizes were obtained using SEM and three distinct morphologies viz., rod, diamond and spindle were clearly distinguished by TEM. All the three samples were characterized by FT-IR, PXRD, UVDRS, PL, XPS and BET, and the effect of the morphologies of MIL-88 A (Fe) on the photocatalytic degradation of Rhodamine B (RhB) was studied under sunlight. The addition of an H 2 O 2 electron acceptor can markedly enhance the photocatalytic Rhodamine B degradation of MIL-88 A(Fe). Among these three, rod-shaped morphology of MIL-88 A(Fe) shows the higher photocatalytic effect for the degradation of Rhodamine B under sunlight due to its lower band gap, high surface area, and lower electronhole recombination rate which enable them the transfer of electrons for the photocatalytic degradation. We found that 98% degradation of RhB in 50 min has taken place by using r-MIL-88 A(Fe) as the catalyst under sunlight.
Stationary energy storage methods such as flow batteries are one of the best options to integrate with smart power grids. Though electrochemical energy storage using flow battery technologies has been successfully demonstrated since the 1970s, the introduction of ionic liquids into the field of energy storage introduces new dimensions in this field. This reliable energy storage technology can provide significantly more flexibility when incorporated with the synergic effects of ionic liquids. This mini-review enumerates the present trends in redox flow battery designs and the use of ionic liquids as electrolytes, membranes, redox couples, etc. explored in these designs. This review specifically intends to provide an overview of the research prospects of ionic liquids for redox flow batteries (RFB).
We have demonstrated the photocatalytic efficiency of the Ag/AgCl@MIL-88A(Fe) composite for the degradation of organic dyes and p-nitrophenol in water.
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